MWE of a much larger code I'm using. It performs a Monte Carlo integration over a KDE (kernel density estimate) for all values located below a certain threshold (the integration method was suggested over at this question: Integrate 2D kernel density estimate) iteratively for a number of points in a list and returns a list made of these results.
import numpy as np from scipy import stats from multiprocessing import Pool import threading # Define KDE integration function. def kde_integration(m_list): # Put some of the values from the m_list into two new lists. m1, m2 = ,  for item in m_list: # x data. m1.append(item) # y data. m2.append(item) # Define limits. xmin, xmax = min(m1), max(m1) ymin, ymax = min(m2), max(m2) # Perform a kernel density estimate on the data: x, y = np.mgrid[xmin:xmax:100j, ymin:ymax:100j] values = np.vstack([m1, m2]) kernel = stats.gaussian_kde(values) # This list will be returned at the end of this function. out_list =  # Iterate through all points in the list and calculate for each the integral # of the KDE for the domain of points located below the value of that point # in the KDE. for point in m_list: # Compute the point below which to integrate. iso = kernel((point, point)) # Sample KDE distribution sample = kernel.resample(size=1000) #Choose number of cores and split input array. cores = 4 torun = np.array_split(sample, cores, axis=1) # Print number of active threads. print threading.active_count() #Calculate pool = Pool(processes=cores) results = pool.map(kernel, torun) #Reintegrate and calculate results insample_mp = np.concatenate(results) < iso # Integrate for all values below iso. integral = insample_mp.sum() / float(insample_mp.shape) # Append integral value for this point to list that will return. out_list.append(integral) return out_list # Generate some random two-dimensional data: def measure(n): "Measurement model, return two coupled measurements." m1 = np.random.normal(size=n) m2 = np.random.normal(scale=0.5, size=n) return m1+m2, m1-m2 # Create list to pass to KDE integral function. m_list =  for i in range(100): m1, m2 = measure(5) m_list.append(m1.tolist()) m_list.append(m2.tolist()) # Call KDE integration function. print 'Integral result: ', kde_integration(m_list)
multiprocessing in the code was suggested over at this question Speed up sampling of kernel estimate to speed up the code (which it does up to ~3.4x).
The code works ok until I try to pass to the KDE function a list of more than ~62-63 elements (ie: I set a value over 63 in the line
for i in range(100)) If I do that I get the following error:
Traceback (most recent call last): File "~/gauss_kde_temp.py", line 78, in <module> print 'Integral result: ', kde_integration(m_list) File "~/gauss_kde_temp.py", line 48, in kde_integration pool = Pool(processes=cores) File "/usr/lib/python2.7/multiprocessing/__init__.py", line 232, in Pool return Pool(processes, initializer, initargs, maxtasksperchild) File "/usr/lib/python2.7/multiprocessing/pool.py", line 144, in __init__ self._worker_handler.start() File "/usr/lib/python2.7/threading.py", line 494, in start _start_new_thread(self.__bootstrap, ()) thread.error: can't start new thread
usually (9 out of 10 times) around the active thread
374. I'm way out of my league in terms of
python coding here and I have no clue as to how I could fix this issue. Any help will be much appreciated.
I tried adding a
while loop to prevent the code from using too many threads. What I did was replacing the
print threading.active_count() line by this bit of code:
# Print number of active threads. exit_loop = True while exit_loop: if threading.active_count() < 300: exit_loop = False else: # Pause for 10 seconds. time.sleep(10.) print 'waiting: ', threading.active_count()
The code halted (ie: got stuck inside the loop) when it reached
302 active threads. I waited for more than 10 minutes and the code never exited the loop and the number of active threads never dropped from
302. Shouldn't the number of active threads diminish after a while?